This patch adds build and driver logic for the "mlxbf_gige"
Ethernet driver from Mellanox Technologies. The second
generation BlueField SoC from Mellanox supports an
out-of-band GigaBit Ethernet management port to the Arm
subsystem.  This driver supports TCP/IP network connectivity
for that port, and provides back-end routines to handle
basic ethtool requests.

The driver interfaces to the Gigabit Ethernet block of
BlueField SoC via MMIO accesses to registers, which contain
control information or pointers describing transmit and
receive resources.  There is a single transmit queue, and
the port supports transmit ring sizes of 4 to 256 entries.
There is a single receive queue, and the port supports
receive ring sizes of 32 to 32K entries. The transmit and
receive rings are allocated from DMA coherent memory. There
is a 16-bit producer and consumer index per ring to denote
software ownership and hardware ownership, respectively.

The main driver logic such as probe(), remove(), and netdev
ops are in "mlxbf_gige_main.c".  Logic in "mlxbf_gige_rx.c"
and "mlxbf_gige_tx.c" handles the packet processing for
receive and transmit respectively.

The logic in "mlxbf_gige_ethtool.c" supports the handling
of some basic ethtool requests: get driver info, get ring
parameters, get registers, and get statistics.

The logic in "mlxbf_gige_mdio.c" is the driver controlling
the Mellanox BlueField hardware that interacts with a PHY
device via MDIO/MDC pins.  This driver does the following:
  - At driver probe time, it configures several BlueField MDIO
    parameters such as sample rate, full drive, voltage and MDC
  - It defines functions to read and write MDIO registers and
    registers the MDIO bus.
  - It defines the phy interrupt handler reporting a
    link up/down status change
  - This driver's probe is invoked from the main driver logic
    while the phy interrupt handler is registered in ndo_open.

Driver limitations
  - Only supports 1Gbps speed
  - Only supports GMII protocol
  - Supports maximum packet size of 2KB
  - Does not support scatter-gather buffering

Testing
  - Successful build of kernel for ARM64, ARM32, X86_64
  - Tested ARM64 build on FastModels & Palladium
  - Tested ARM64 build on several Mellanox boards that are built with
    the BlueField-2 SoC.  The testing includes coverage in the areas
    of networking (e.g. ping, iperf, ifconfig, route), file transfers
    (e.g. SCP), and various ethtool options relevant to this driver.

Signed-off-by: David Thompson <davthompson@nvidia.com>
Signed-off-by: Asmaa Mnebhi <asmaa@nvidia.com>
Reviewed-by: Liming Sun <limings@nvidia.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

The Broadcom UniMAC MDIO bus from mdio-bcm-unimac module comes too late.
So, GENET cannot find the ethernet PHY on UniMAC MDIO bus. This leads
GENET fail to attach the PHY as following log:

bcmgenet fd580000.ethernet: GENET 5.0 EPHY: 0x0000
...
could not attach to PHY
bcmgenet fd580000.ethernet eth0: failed to connect to PHY
uart-pl011 fe201000.serial: no DMA platform data
libphy: bcmgenet MII bus: probed
...
unimac-mdio unimac-mdio.-19: Broadcom UniMAC MDIO bus

It is not just coming too late, there is also no way for the module
loader to figure out the dependency between GENET and its MDIO bus
driver unless we provide this MODULE_SOFTDEP hint.

This patch adds the soft dependency to load mdio-bcm-unimac module
before genet module to fix this issue.

Buglink: https://bugzilla.kernel.org/show_bug.cgi?id=213485
Fixes: 9a4e7969

 ("net: bcmgenet: utilize generic Broadcom UniMAC MDIO controller driver")
Signed-off-by: Jian-Hong Pan <jhp@endlessos.org>
Signed-off-by: Florian Fainelli <f.fainelli@gmail.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

parameter dst always points to null.

Signed-off-by: zhang kai <zhangkaiheb@126.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

Simply get a pointer to the data in the register payload instead of
copying it to a temporary buffer.

Signed-off-by: Ido Schimmel <idosch@nvidia.com>
Reviewed-by: Jiri Pirko <jiri@nvidia.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

https://patchwork.kernel.org/project/netdevbpf/list/?series=506637&state=*

- Remove unused variable
- Use correct integer type for string formatting.
- Remove `inline` in C files

Fixes: 9c1a59a2 ("gve: DQO: Add ring allocation and initialization")
Fixes: a57e5de4

 ("gve: DQO: Add TX path")
Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

Xin Long says:

====================
sctp: make the PLPMTUD probe more effective and efficient

As David Laight noticed, it currently takes quite some time to find
the optimal pmtu in the Search state, and also lacks the black hole
detection in the Search Complete state. This patchset is to address
them to mke the PLPMTUD probe more effective and efficient.
====================

Signed-off-by: David S. Miller <davem@davemloft.net>

These is no need to wait for 'interval' period for the next probe
if the last probe is already acked in search state. The 'interval'
period waiting should be only for probe failure timeout and the
current pmtu check when it's in search complete state.

This change will shorten the probe time a lot in search state, and
also fix the document accordingly.

Signed-off-by: Xin Long <lucien.xin@gmail.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

Currently the PLPMUTD probe will stop for a long period (interval * 30)
after it enters search complete state. If there's a pmtu change on the
route path, it takes a long time to be aware if the ICMP TooBig packet
is lost or filtered.

As it says in rfc8899#section-4.3:

  "A DPLPMTUD method MUST NOT rely solely on this method."
  (ICMP PTB message).

This patch is to enable the other method for search complete state:

  "A PL can use the DPLPMTUD probing mechanism to periodically
   generate probe packets of the size of the current PLPMTU."

With this patch, the probe will continue with the current pmtu every
'interval' until the PMTU_RAISE_TIMER 'timeout', which we implement
by adding raise_count to raise the probe size when it counts to 30
and removing the SCTP_PL_COMPLETE check for PMTU_RAISE_TIMER.

Signed-off-by: Xin Long <lucien.xin@gmail.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

Vladimir Oltean says:

====================
Document the NXP SJA1110 switch as supported

Now that most of the basic work for SJA1110 support has been done in the
sja1105 DSA driver, let's add the missing documentation bits to make it
clear that the driver can be used.
====================

Signed-off-by: David S. Miller <davem@davemloft.net>

Mention support for the SJA1110 in menuconfig.

Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

Denote that the new switch generation is supported, detail its pin
strapping options (with differences compared to SJA1105) and explain how
MDIO access to the internal 100base-T1 and 100base-TX PHYs is performed.

Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

Bailey Forrest says:

====================
gve: Introduce DQO descriptor format

DQO is the descriptor format for our next generation virtual NIC. The existing
descriptor format will be referred to as "GQI" in the patch set.

One major change with DQO is it uses dual descriptor rings for both TX and RX
queues.

The TX path uses a TX queue to send descriptors to HW, and receives packet
completion events on a TX completion queue.

The RX path posts buffers to HW using an RX buffer queue and receives incoming
packets on an RX queue.

One important note is that DQO descriptors and doorbells are little endian. We
continue to use the existing big endian control plane infrastructure.

The general format of the patch series is:
- Refactor existing code/data structures to be shared by DQO
- Expand admin queues to support DQO device setup
- Expand data structures and device setup to support DQO
- Add logic to setup DQO queues
- Implement datapath
====================

Signed-off-by: David S. Miller <davem@davemloft.net>

The RX queue has an array of `gve_rx_buf_state_dqo` objects. All
allocated pages have an associated buf_state object. When a buffer is
posted on the RX buffer queue, the buffer ID will be the buf_state's
index into the RX queue's array.

On packet reception, the RX queue will have one descriptor for each
buffer associated with a received packet. Each RX descriptor will have
a buffer_id that was posted on the buffer queue.

Notable mentions:

- We use a default buffer size of 2048 bytes. Based on page size, we
  may post separate sections of a single page as separate buffers.

- The driver holds an extra reference on pages passed up the receive
  path with an skb and keeps these pages on a list. When posting new
  buffers to the NIC, we check if any of these pages has only our
  reference, or another buffer sized segment of the page has no
  references. If so, it is free to reuse. This page recycling approach
  is a common netdev optimization that reduces page alloc/free calls.

- Pages in the free list have a page_count bias in order to avoid an
  atomic increment of pagecount every time we attempt to reuse a page.
  # references = page_count() - bias

- In order to track when a page is safe to reuse, we keep track of the
  last offset which had a single SKB reference. When this occurs, it
  implies that every single other offset is reusable. Otherwise, we
  don't know if offsets can be safely reused.

- We maintain two free lists of pages. List #1 (recycled_buf_states)
  contains pages we know can be reused right away. List #2
  (used_buf_states) contains pages which cannot be used right away. We
  only attempt to get pages from list #2 when list #1 is empty. We only
  attempt to use a small fixed number pages from list #2 before giving
  up and allocating a new page. Both lists are FIFOs in hope that by the
  time we attempt to reuse a page, the references were dropped.

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

TX SKBs will have their buffers DMA mapped with the device. Each buffer
will have at least one TX descriptor associated. Each SKB will also have
a metadata descriptor.

Each TX queue maintains an array of `gve_tx_pending_packet_dqo` objects.
Every TX SKB will have an associated pending_packet object. A TX SKB's
descriptors will use its pending_packet's index as the completion tag,
which will be returned on the TX completion queue.

The device implements a "flow-miss model". Most packets will simply
receive a packet completion. The flow-miss system may choose to process
a packet based on its contents. A TX packet which experiences a flow
miss would receive a miss completion followed by a later reinjection
completion. The miss-completion is received when the packet starts to be
processed by the flow-miss system and the reinjection completion is
received when the flow-miss system completes processing the packet and
sends it on the wire.

Notable mentions:

- Buffers may be freed after receiving the miss-completion, but in order
  to avoid packet reordering, we do not complete the SKB until receiving
  the reinjection completion.

- The driver must robustly handle the unlikely scenario where a miss
  completion does not have an associated reinjection completion. This is
  accomplished by maintaining a list of packets which have a pending
  reinjection completion. After a short timeout (5 seconds), the
  SKB and buffers are released and the pending_packet is moved to a
  second list which has a longer timeout (60 seconds), where the
  pending_packet will not be reused. When the longer timeout elapses,
  the driver may assume the reinjection completion would never be
  received and the pending_packet may be reused.

- Completion handling is triggered by an interrupt and is done in the
  NAPI poll function. Because the TX path and completion exist in
  different threading contexts they maintain their own lists for free
  pending_packet objects. The TX path uses a lock-free approach to steal
  the list from the completion path.

- Both the TSO context and general context descriptors have metadata
  bytes. The device requires that if multiple descriptors contain the
  same field, each descriptor must have the same value set for that
  field.

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

When interrupts are first enabled, we also set the ratelimits, which
will be static for the entire usage of the device.

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

Allocate the buffer and completion ring structures. Do not populate the
rings yet. That will happen in the respective rx and tx datapath
follow-on patches

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

Add napi netdev device registration, interrupt handling and initial tx
and rx polling stubs. The stubs will be filled in follow-on patches.

Also:
- LRO feature advertisement and handling
- Also update ethtool logic

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

DQO queue creation requires additional parameters:
- TX completion/RX buffer queue size
- TX completion/RX buffer queue address
- TX/RX queue size
- RX buffer size

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

- Add new DQO datapath structures:
  - `gve_rx_buf_queue_dqo`
  - `gve_rx_compl_queue_dqo`
  - `gve_rx_buf_state_dqo`
  - `gve_tx_desc_dqo`
  - `gve_tx_pending_packet_dqo`

- Incorporate these into the existing ring data structures:
  - `gve_rx_ring`
  - `gve_tx_ring`

Noteworthy mentions:

- `gve_rx_buf_state` represents an RX buffer which was posted to HW.
  Each RX queue has an array of these objects and the index into the
  array is used as the buffer_id when posted to HW.

- `gve_tx_pending_packet_dqo` is treated similarly for TX queues. The
  completion_tag is the index into the array.

- These two structures have links for linked lists which are represented
  by 16b indexes into a contiguous array of these structures.
  This reduces memory footprint compared to 64b pointers.

- We use unions for the writeable datapath structures to reduce cache
  footprint. GQI specific members will renamed like DQO members in a
  future patch.

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

General description of rings and descriptors:

TX ring is used for sending TX packet buffers to the NIC. It has the
following descriptors:
- `gve_tx_pkt_desc_dqo` - Data buffer descriptor
- `gve_tx_tso_context_desc_dqo` - TSO context descriptor
- `gve_tx_general_context_desc_dqo` - Generic metadata descriptor

Metadata is a collection of 12 bytes. We define `gve_tx_metadata_dqo`
which represents the logical interpetation of the metadata bytes. It's
helpful to define this structure because the metadata bytes exist in
multiple descriptor types (including `gve_tx_tso_context_desc_dqo`),
and the device requires same field has the same value in all
descriptors.

The TX completion ring is used to receive completions from the NIC.
Having a separate ring allows for completions to be out of order. The
completion descriptor `gve_tx_compl_desc` has several different types,
most important are packet and descriptor completions. Descriptor
completions are used to notify the driver when descriptors sent on the
TX ring are done being consumed. The descriptor completion is only used
to signal that space is cleared in the TX ring. A packet completion will
be received when a packet transmitted on the TX queue is done being
transmitted.

In addition there are "miss" and "reinjection" completions. The device
implements a "flow-miss model". Most packets will simply receive a
packet completion. The flow-miss system may choose to process a packet
based on its contents. A TX packet which experiences a flow miss would
receive a miss completion followed by a later reinjection completion.
The miss-completion is received when the packet starts to be processed
by the flow-miss system and the reinjection completion is received when
the flow-miss system completes processing the packet and sends it on the
wire.

The RX buffer ring is used to send buffers to HW via the
`gve_rx_desc_dqo` descriptor.

Received packets are put into the RX queue by the device, which
populates the `gve_rx_compl_desc_dqo` descriptor. The RX descriptors
refer to buffers posted by the buffer queue. Received buffers may be
returned out of order, such as when HW LRO is enabled.

Important concepts:
- "TX" and "RX buffer" queues, which send descriptors to the device, use
  MMIO doorbells to notify the device of new descriptors.

- "RX" and "TX completion" queues, which receive descriptors from the
  device, use a "generation bit" to know when a descriptor was populated
  by the device. The driver initializes all bits with the "current
  generation". The device will populate received descriptors with the
  "next generation" which is inverted from the current generation. When
  the ring wraps, the current/next generation are swapped.

- It's the driver's responsibility to ensure that the RX and TX
  completion queues are not overrun. This can be accomplished by
  limiting the number of descriptors posted to HW.

- TX packets have a 16 bit completion_tag and RX buffers have a 16 bit
  buffer_id. These will be returned on the TX completion and RX queues
  respectively to let the driver know which packet/buffer was completed.

Bitfields are used to describe descriptor fields. This notation is more
concise and readable than shift-and-mask. It is possible because the
driver is restricted to little endian platforms.

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

Unlike GQI, DQO RX descriptors do not contain the L3 and L4 type of the
packet. L3 and L4 types are necessary in order to set the hash and csum
on RX SKBs correctly.

DQO RX descriptors instead contain a 10 bit PTYPE index. The PTYPE map
enables the device to tell the driver how to map from PTYPE index to
L3/L4 type.

The device doesn't provide any guarantees about the range of possible
PTYPEs, so we just use a 1024 entry array to implement a fast mapping
structure.

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

- In addition to TX and RX queues, DQO has TX completion and RX buffer
  queues.
  - TX completions are received when the device has completed sending a
    packet on the wire.
  - RX buffers are posted on a separate queue form the RX completions.
- DQO descriptor rings are allowed to be smaller than PAGE_SIZE.

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

The currently supported queue formats are:
- GQI_RDA - GQI with raw DMA addressing
- GQI_QPL - GQI with queue page list
- DQO_RDA - DQO with raw DMA addressing

The old `gve_priv.raw_addressing` value is only used for GQI_RDA, so we
remove it in favor of just checking against GQI_RDA

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

The current model uses an integer ID and a fixed size struct for the
parameters of each device option.

The new model allows the device option structs to grow in size over
time. A driver may assume that changes to device option structs will
always be appended.

New device options will also generally have a
`supported_features_mask` so that the driver knows which fields within a
particular device option are enabled.

`gve_device_option.feat_mask` is changed to `required_features_mask`,
and it is a bitmask which must match the value expected by the driver.
This gives the device the ability to break backwards compatibility with
old drivers for certain features by blocking the old drivers from trying
to use the feature.

We maintain ABI compatibility with the old model for
GVE_DEV_OPT_ID_RAW_ADDRESSING in case a driver is using a device which
does not support the new model.

This patch introduces some new terminology:

RDA - Raw DMA Addressing - Buffers associated with SKBs are directly DMA
      mapped and read/updated by the device.

QPL - Queue Page Lists - Driver uses bounce buffers which are DMA mapped
      with the device for read/write and data is copied from/to SKBs.

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

Using `page_offset` like a boolean means a page may only be split into
two sections. With page sizes larger than 4k, this can be very wasteful.
Future commits in this patchset use `struct gve_rx_slot_page_info` in a
way which supports a fixed buffer size and a variable page size.

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

Future use cases will have a different padding value.

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

These functions will be shared by the GQI and DQO variants of the GVNIC
driver as of follow-up patches in this series.

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

DQO is a new descriptor format for our next generation virtual NIC.

Signed-off-by: Bailey Forrest <bcf@google.com>
Reviewed-by: Willem de Bruijn <willemb@google.com>
Reviewed-by: Catherine Sullivan <csully@google.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

Modify the netdev_dbg content from int to char * in usbnet_defer_kevent(),
this looks more readable.

Signed-off-by: Yajun Deng <yajun.deng@linux.dev>
Signed-off-by: David S. Miller <davem@davemloft.net>

Steen Hegelund says:

====================
Adding the Sparx5i Switch Driver

This series provides the Microchip Sparx5i Switch Driver

The SparX-5 Enterprise Ethernet switch family provides a rich set of
Enterprise switching features such as advanced TCAM-based VLAN and QoS
processing enabling delivery of differentiated services, and security
through TCAMbased frame processing using versatile content aware processor
(VCAP). IPv4/IPv6 Layer 3 (L3) unicast and multicast routing is supported
with up to 18K IPv4/9K IPv6 unicast LPM entries and up to 9K IPv4/3K IPv6
(S,G) multicast groups. L3 security features include source guard and
reverse path forwarding (uRPF) tasks. Additional L3 features include
VRF-Lite and IP tunnels (IP over GRE/IP).

The SparX-5 switch family features a highly flexible set of Ethernet ports
with support for 10G and 25G aggregation links, QSGMII, USGMII, and
USXGMII.  The device integrates a powerful 1 GHz dual-core ARM® Cortex®-A53
CPU enabling full management of the switch and advanced Enterprise
applications.

The SparX-5 switch family targets managed Layer 2 and Layer 3 equipment in
SMB, SME, and Enterprise where high port count 1G/2.5G/5G/10G switching
with 10G/25G aggregation links is required.

The SparX-5 switch family consists of following SKUs:

  VSC7546 SparX-5-64 supports up to 64 Gbps of bandwidth with the following
  primary port configurations.
   - 6 ×10G
   - 16 × 2.5G + 2 × 10G
   - 24 × 1G + 4 × 10G

  VSC7549 SparX-5-90 supports up to 90 Gbps of bandwidth with the following
  primary port configurations.
   - 9 × 10G
   - 16 × 2.5G + 4 × 10G
   - 48 × 1G + 4 × 10G

  VSC7552 SparX-5-128 supports up to 128 Gbps of bandwidth with the
  following primary port configurations.
   - 12 × 10G
   - 6 x 10G + 2 x 25G
   - 16 × 2.5G + 8 × 10G
   - 48 × 1G + 8 × 10G

  VSC7556 SparX-5-160 supports up to 160 Gbps of bandwidth with the
  following primary port configurations.
   - 16 × 10G
   - 10 × 10G + 2 × 25G
   - 16 × 2.5G + 10 × 10G
   - 48 × 1G + 10 × 10G

  VSC7558 SparX-5-200 supports up to 200 Gbps of bandwidth with the
  following primary port configurations.
   - 20 × 10G
   - 8 × 25G

In addition, the device supports one 10/100/1000/2500/5000 Mbps
SGMII/SerDes node processor interface (NPI) Ethernet port.

Time sensitive networking (TSN) is supported through a comprehensive set of
features including frame preemption, cut-through, frame replication and
elimination for reliability, enhanced scheduling: credit-based shaping,
time-aware shaping, cyclic queuing, and forwarding, and per-stream policing
and filtering.

Together with IEEE 1588 and IEEE 802.1AS support, this guarantees
low-latency deterministic networking for Industrial Ethernet.

The Sparx5i support is developed on the PCB134 and PCB135 evaluation boards.

- PCB134 main networking features:
  - 12x SFP+ front 10G module slots (connected to Sparx5i through SFI).
  - 8x SFP28 front 25G module slots (connected to Sparx5i through SFI high
    speed).
  - Optional, one additional 10/100/1000BASE-T (RJ45) Ethernet port
    (on-board VSC8211 PHY connected to Sparx5i through SGMII).

- PCB135 main networking features:
  - 48x1G (10/100/1000M) RJ45 front ports using 12xVSC8514 QuadPHY’s each
    connected to VSC7558 through QSGMII.
  - 4x10G (1G/2.5G/5G/10G) RJ45 front ports using the AQR407 10G QuadPHY
    each port connects to VSC7558 through SFI.
  - 4x SFP28 25G module slots on back connected to VSC7558 through SFI high
    speed.
  - Optional, one additional 1G (10/100/1000M) RJ45 port using an on-board
    VSC8211 PHY, which can be connected to VSC7558 NPI port through SGMII
    using a loopback add-on PCB)

This series provides support for:
  - SFPs and DAC cables via PHYLINK with a number of 5G, 10G and 25G
    devices and media types.
  - Port module configuration for 10M to 25G speeds with SGMII, QSGMII,
    1000BASEX, 2500BASEX and 10GBASER as appropriate for these modes.
  - SerDes configuration via the Sparx5i SerDes driver (see below).
  - Host mode providing register based injection and extraction.
  - Switch mode providing MAC/VLAN table learning and Layer2 switching
    offloaded to the Sparx5i switch.
  - STP state, VLAN support, host/bridge port mode, Forwarding DB, and
    configuration and statistics via ethtool.

More support will be added at a later stage.

The Sparx5i Chip Register Model can be browsed at this location:
https://github.com/microchip-ung/sparx-5_reginfo
and the datasheet is available here:
https://ww1.microchip.com/downloads/en/DeviceDoc/SparX-5_Family_L2L3_Enterprise_10G_Ethernet_Switches_Datasheet_00003822B.pdf

The series depends on the following series currently on their way
into the kernel:

- 25G Base-R phy mode
  Link: https://lore.kernel.org/r/20210611125453.313308-1-steen.hegelund@microchip.com/
- Sparx5 Reset Driver
  Link: https://lore.kernel.org/r/20210416084054.2922327-1-steen.hegelund@microchip.com/



ChangeLog:
v5:
    - cover letter
        - updated the description to match the latest data sheets
    - basic driver
        - added error message in case of reset controller error
        - port struct: replacing has_sfp with inband, adding pause_adv
    - host mode
        - port cleanup: unregisters netdevs and then removes phylink etc
        - checking for pause_adv when comparing port config changes
        - getting duplex and pause state in the link_up callback.
        - getting inband, autoneg and pause_adv config in the pcs_config
          callback.
    - port
        - use only the pause_adv bits when getting aneg status
        - use the inband state when updating the PCS and port config
v4:
    - basic driver:
        Using devm_reset_control_get_optional_shared to get the reset
        control, and let the reset framework check if it is valid.
    - host mode (phylink):
        Use the PCS operations to get state and update configuration.
        Removed the setting of interface modes.  Let phylink control this.
        Using the new 5gbase-r and 25gbase-r modes.
        Using a helper function to check if one of the 3 base-r modes has
        been selected.
        Currently it will not be possible to change the interface mode by
        changing the speed (e.g via ethtool).  This will be added later.
v3:
    - basic driver:
        - removed unneeded braces
        - release reference to ports node after use
        - use dev_err_probe to handle DEFER
        - update error value when bailing out (a few cases)
        - updated formatting of port struct and grouping of bool values
        - simplified the spx5_rmw and spx5_inst_rmw inline functions
    - host mode (netdev):
        - removed lockless flag
        - added port timer init
    - host mode (packet - manual injection):
        - updated error counters in error situations
        - implemented timer handling of watermark threshold: stop and
          restart netif queues.
        - fixed error message handling (rate limited)
        - fixed comment style error
        - used DIV_ROUND_UP macro
        - removed a debug message for open ports

v2:
    - Updated bindings:
        - drop minItems for the reg property
    - Statistics implementation:
        - Reorganized statistics into ethtool groups:
            eth-phy, eth-mac, eth-ctrl, rmon
          as defined by the IEEE 802.3 categories and RFC 2819.
        - The remaining statistics are provided by the classic ethtool
          statistics command.
    - Hostmode support:
        - Removed netdev renaming
        - Validate ethernet address in sparx5_set_mac_address()
====================

Signed-off-by: David S. Miller <davem@davemloft.net>

This provides the configuration for the currently available evaluation
boards PCB134 and PCB135.

The series depends on the following series currently on its way
into the kernel:

- Sparx5 Reset Driver
  Link: https://lore.kernel.org/r/20210416084054.2922327-1-steen.hegelund@microchip.com/



Signed-off-by: Steen Hegelund <steen.hegelund@microchip.com>
Signed-off-by: Lars Povlsen <lars.povlsen@microchip.com>
Signed-off-by: Bjarni Jonasson <bjarni.jonasson@microchip.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

This adds statistic counters for the network interfaces provided
by the driver.  It also adds CPU port counters (which are not
exposed by ethtool).
This also adds support for configuring the network interface
parameters via ethtool: speed, duplex, aneg etc.

Signed-off-by: Steen Hegelund <steen.hegelund@microchip.com>
Signed-off-by: Bjarni Jonasson <bjarni.jonasson@microchip.com>
Signed-off-by: Lars Povlsen <lars.povlsen@microchip.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

This configures the Sparx5 calendars according to the bandwidth
requested in the Device Tree nodes.
It also checks if the total requested bandwidth is within the
specs of the detected Sparx5 models limits.

Signed-off-by: Steen Hegelund <steen.hegelund@microchip.com>
Signed-off-by: Bjarni Jonasson <bjarni.jonasson@microchip.com>
Signed-off-by: Lars Povlsen <lars.povlsen@microchip.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

This adds SwitchDev support by hardware offloading the
software bridge.

Signed-off-by: Steen Hegelund <steen.hegelund@microchip.com>
Signed-off-by: Bjarni Jonasson <bjarni.jonasson@microchip.com>
Signed-off-by: Lars Povlsen <lars.povlsen@microchip.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

This adds Sparx5 VLAN support.

Sparx5 has more VLAN features than provided here, but these will be added
in later series. For now we only add the basic L2 features.

Signed-off-by: Steen Hegelund <steen.hegelund@microchip.com>
Signed-off-by: Bjarni Jonasson <bjarni.jonasson@microchip.com>
Signed-off-by: Lars Povlsen <lars.povlsen@microchip.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

This adds the Sparx5 MAC tables: listening for MAC table updates and
updating on request.

Signed-off-by: Steen Hegelund <steen.hegelund@microchip.com>
Signed-off-by: Bjarni Jonasson <bjarni.jonasson@microchip.com>
Signed-off-by: Lars Povlsen <lars.povlsen@microchip.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

This add configuration of the Sparx5 port module instances.

Sparx5 has in total 65 logical ports (denoted D0 to D64) and 33
physical SerDes connections (S0 to S32).  The 65th port (D64) is fixed
allocated to SerDes0 (S0). The remaining 64 ports can in various
multiplexing scenarios be connected to the remaining 32 SerDes using
QSGMII, or USGMII or USXGMII extenders. 32 of the ports can have a 1:1
mapping to the 32 SerDes.

Some additional ports (D65 to D69) are internal to the device and do not
connect to port modules or SerDes macros. For example, internal ports are
used for frame injection and extraction to the CPU queues.

The 65 logical ports are split up into the following blocks.

- 13 x 5G ports (D0-D11, D64)
- 32 x 2G5 ports (D16-D47)
- 12 x 10G ports (D12-D15, D48-D55)
- 8 x 25G ports (D56-D63)

Each logical port supports different line speeds, and depending on the
speeds supported, different port modules (MAC+PCS) are needed. A port
supporting 5 Gbps, 10 Gbps, or 25 Gbps as maximum line speed, will have a
DEV5G, DEV10G, or DEV25G module to support the 5 Gbps, 10 Gbps (incl 5
Gbps), or 25 Gbps (including 10 Gbps and 5 Gbps) speeds. As well as, it
will have a shadow DEV2G5 port module to support the lower speeds
(10/100/1000/2500Mbps). When a port needs to operate at lower speed and the
shadow DEV2G5 needs to be connected to its corresponding SerDes

Not all interface modes are supported in this series, but will be added at
a later stage.

Signed-off-by: Steen Hegelund <steen.hegelund@microchip.com>
Signed-off-by: Bjarni Jonasson <bjarni.jonasson@microchip.com>
Signed-off-by: Lars Povlsen <lars.povlsen@microchip.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

This patch adds netdevs and phylink support for the ports in the switch.
It also adds register based injection and extraction for these ports.

Frame DMA support for injection and extraction will be added in a later
series.

Signed-off-by: Steen Hegelund <steen.hegelund@microchip.com>
Signed-off-by: Bjarni Jonasson <bjarni.jonasson@microchip.com>
Signed-off-by: Lars Povlsen <lars.povlsen@microchip.com>
Signed-off-by: David S. Miller <davem@davemloft.net>

This adds the Sparx5 basic SwitchDev driver framework with IO range
mapping, switch device detection and core clock configuration.

Support for ports, phylink, netdev, mactable etc. are in the following
patches.

Signed-off-by: Steen Hegelund <steen.hegelund@microchip.com>
Signed-off-by: Bjarni Jonasson <bjarni.jonasson@microchip.com>
Signed-off-by: Lars Povlsen <lars.povlsen@microchip.com>
Reviewed-by: Philipp Zabel <p.zabel@pengutronix.de>
Signed-off-by: David S. Miller <davem@davemloft.net>

Document the Sparx5 switch device driver bindings

Signed-off-by: Steen Hegelund <steen.hegelund@microchip.com>
Signed-off-by: Lars Povlsen <lars.povlsen@microchip.com>
Signed-off-by: Bjarni Jonasson <bjarni.jonasson@microchip.com>
Reviewed-by: Rob Herring <robh@kernel.org>
Signed-off-by: David S. Miller <davem@davemloft.net>